Volume 5

Toxicology: Open Access

Page 14

Notes:

conference

series

.com

May 06-07, 2019 Tokyo, Japan

20

th

World Congress on

Toxicology Congress 2019

May 06-07, 2019

Toxicology and Pharmacology

DNase/endonuclease network: A new target for mitigation of acute nephrotoxicity

D

eoxyribonucleases (DNases) universally induce irreversible cell death by fragmenting DNA in response to cell injury. All

of the nine known cell death DNases are endonucleases. Despite that most of the DNase activity is used after cell death,

a genetic inactivation of DNases provide protection of cells and tissues against DNA breaks induced by cytotoxic stimuli and

partially protect against tissue injury. Therefore, DNases act before the point-of-no-return in cell death and can be potentially

used as therapeutic targets for tissue protection against injury. Our studies identified two DNases, DNase I and EndoG, as

being responsible for tubular epithelial toxicity during acute kidney injury induced by Cisplatin, rhabdomyolysis or ischemia.

However, inhibitors of DNases are not available. The aim of this study was to identify DNase inhibitors, which might be used

for mitigation of acute kidney injury. To identify DNase inhibitors, we have developed a high-throughput screening assay

based on a proprietary fluorescent probe. This assay allowed the identification of several new inhibitors of deoxyribonuclease

I (DNase I), which were also active against two other DNases, endonucleases G (EndoG) and Deoxyribonuclease II (DNase

II). The DNase inhibitors were able to significantly protect kidney tubular epithelial cells

in vitro

and mouse kidneys

in vivo

against acute kidney toxicity induced by Cisplatin, glycerol (rhabdomyolysis), or renal ischemia-reperfusion. The inhibitors

showed no toxicity

in vivo

at 5x therapeutic doses. DNases can be used as a therapeutic target for mitigation of toxic or hypoxic

acute kidney injury. The identified DNase inhibitors or similar compounds have a great potential for tissue protection against

toxic kidney failure. Considering that DNases are expressed and responsible for cell death in all tested cells, tissues and animal

models, it is likely that the same compounds may be used for universal tissue protection against various injuries.

Biography

Alexei G Basnakian has completed his PhD and DSc degrees from the Russian Academy of Medical Science, both in the field of DNA-degrading enzymes.

He had Post-doctoral trainings in Molecular Biology at the Harvard Medical School and in Toxicology/Cancer Research at the National Center for Toxicological

Research/U.S. Food and Drug Administration. He is a tenured Professor at the Department of Pharmacology and Toxicology and also Director of the DNA Damage

and Toxicology Core Center at the University of Arkansas for Medical Sciences and Research Career Scientist at the Veterans Hospital in Little Rock, USA. He is

the author of 87 peer-reviewed papers and 14 reviews or book chapters. He is an Editorial Board Member of four biomedical journals and also a Member of NIH,

AHA and VA grant study sections. His research interests are in DNases/endonucleases and DNA damage associated with toxicity, anti-cancer therapy, tissue injury

and cell death.

basnakianalexeig@uams.edu

Alexei G Basnakian

University of Arkansas for Medical Sciences, USA

Alexei G Basnakian, Toxicol Open Access 2019, Volume 5

DOI: 10.4172/2476-2067-C1-007